Molecular Characterization and Human T-Cell Responses to a Member of a Novel Mycobacterium tuberculosis mtb39 Gene Family

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Infection and Immunity, June 1999, p. 2941-2950, Vol. 67, No. 6
0019-9567/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Molecular Characterization and Human T-Cell Responses to a Member of a Novel Mycobacterium tuberculosis mtb39 Gene Family

Davin C. Dillon,¹^,^* Mark R. Alderson,¹ Craig H. Day,¹ David M. Lewinsohn,² Rhea Coler,² Teresa Bement,¹ Antonio Campos-Neto,² Y. A. W. Skeiky,¹ Ian M. Orme,³ Alan Roberts,³ Sean Steen,¹ Wilfried Dalemans,⁴ Roberto Badaro,⁵ and Steven G. Reed¹^,²^,⁶

Corixa Corporation¹ and Infectious Disease Research Institute,² Seattle, Washington 98104; Department of Microbiology, Colorado State University, Fort Collins, Colorado 80523³; SmithKline Beecham Biologicals, Rixensart, Belgium⁴; Federal University of Bahia, Salvador, Brazil⁵; and Department of Pathobiology, University of Washington, Seattle, Washington 98195⁶

Received 11 August 1998/Returned for modification 16 September 1998/Accepted 22 March 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

We have used expression screening of a genomic Mycobacterium tuberculosis library with tuberculosis (TB) patient sera to identifynovel genes that may be used diagnostically or in the developmentof a TB vaccine. Using this strategy, we have cloned a novel gene,termed mtb39a, that encodes a 39-kDa protein. Molecular characterizationrevealed that mtb39a is a member of a family of three highly relatedgenes that are conserved among strains of M. tuberculosis andMycobacterium bovis BCG but not in other mycobacterial speciestested. Immunoblot analysis demonstrated the presence of Mtb39Ain M. tuberculosis lysate but not in culture filtrate proteins(CFP), indicating that it is not a secreted antigen. This conclusionis strengthened by the observation that a human T-cell clone specificfor purified recombinant Mtb39A protein recognized autologousdendritic cells infected with TB or pulsed with purified proteinderivative (PPD) but did not respond to M. tuberculosis CFP. Purifiedrecombinant Mtb39A elicited strong T-cell proliferative and gammainterferon responses in peripheral blood mononuclear cells from9 of 12 PPD-positive individuals tested, and overlapping peptideswere used to identify a minimum of 10 distinct T-cell epitopes.Additionally, mice immunized with mtb39a DNA have shown increasedprotection from M. tuberculosis challenge, as indicated by a reductionof bacterial load. The human T-cell responses and initial animalstudies provide support for further evaluation of this antigenas a possible component of a subunit vaccine for M. tuberculosis.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Approximately 1.7 billion people are infected with Mycobacterium tuberculosis (21), the causative agent of tuberculosis(TB). TB is a leading cause of infectious mortality worldwide,accounting for 2.9 million deaths annually (5). The emergenceof drug-resistant strains and coinfections with human immunodeficiencyvirus (HIV) has led to an increased mortality of TB cases (7,27, 40). The only currently available vaccine to prevent TBis Mycobacterium bovis BCG, a live attenuated mycobacterial strainfirst developed in 1921 (11). However, individual trials withBCG have yielded highly variable results (6), and a recentmeta-analysis of BCG as a vaccine to prevent TB has shown it tohave limited efficacy, providing only 50% protection from pulmonaryTB (14). In addition, BCG can cause disseminated disease inimmunocompromised individuals (10, 43, 44). The variableefficacy of BCG, coupled with the inherent difficulties of standardizationand safety of a live vaccine, has generated interest in the developmentof a subunit vaccine based on immunodominant M. tuberculosisantigens.

Immunity to M. tuberculosis depends upon the cellular immune response. In studies in the mouse model for TB, cellular depletionand adoptive transfer experiments have demonstrated a protectiverole for both CD4⁺ and CD8⁺ T lymphocytes (26, 29, 30, 34). In addition, gamma interferon(IFN- $gamma$ ) is critical for immunity to TB since disruption of theIFN- $gamma$ gene in mice resulted in increased susceptibility to TBinfection (16, 18). In humans, evidence for the need of anintact cellular immune response for resistance to TB also exists.Impaired cellular immunity resulting from HIV infection leadsto increased likelihood of active tuberculosis (9, 12), andthe need for IFN- $gamma$ is suggested by increased susceptibility toatypical mycobacteria in individuals with a mutated IFN- $gamma$ receptor(20, 28).

The identification of M. tuberculosis antigens capable of eliciting T-cell responses has been pursued by a variety of procedures,including the biochemical fractionation and purification of M.tuberculosis proteins (4, 36) and the utilization of mycobacterium-specificmonoclonal antibodies to screen genomic M. tuberculosis expressionlibraries (13, 17, 41). A strategy that has been less widelyexploited is expression cloning of M. tuberculosis genomic librariesby using sera from patients with active or recently treated infections(2). The rationale for this approach is based on the hypothesisthat some M. tuberculosis T-cell antigens are capable of generatinga detectable humoral response in individuals with active disease.Since serological responses to protein antigens are T cell dependentand an increase in mycobacterial antigen-specific immunoglobulinG in sera from TB patients compared to sera from healthy purifiedprotein derivative (PPD)-positive controls has previously beenreported (39), we reasoned that pools of sera from individualswith active or recently treated disease could be used as a toolto identify T-cellantigens.

In this study, we have used serological expression cloning to identify a novel T-cell antigen from M. tuberculosis, referredto as Mtb39A. Recombinant Mtb39A protein elicited strong T-cellresponses in 75% of healthy PPD-positive individuals, and mtb39aDNA immunization of mice provided partial protection against M.tuberculosis challenge. These results support further evaluationof the antigen as a component of a subunitvaccine.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Bacterial strains. M. tuberculosis strains H37Rv, H37Ra, and Erdman were gifts from the Seattle VA Hospital; strain C was a gift from Lee Riley,University of California, Berkeley; and Mycobacterium bovis BCGand Mycobacterium leprae (Pasteur) were obtained from GenesisCorp., Auckland, New Zealand. The following other species of mycobacteriawere obtained from the American Type Culture Collection (Rockville,Md.): M. vaccae (ATCC 15483), M. avium avium (ATCC 35718), M.chelonae (ATCC 14472), M. fortuitum (ATCC 6841), M. gordonae (ATCC14470), M. scrofulaceum (ATCC 19981), and M. smegmatis (ATCC19420).

Patient sera and peripheral blood mononuclear cells (PBMCs). A pool of M. tuberculosis patient sera was made from three samples. Patient 1 serum was obtained from a 52-year-old male withpulmonary TB (4+ acid-fast bacillus [AFB]) 2 months after initiationof treatment (16-mm PPD; patient had a history of vaccinationwith BCG). Patient 2 serum was obtained from an 18-year-old femalewith pulmonary TB (2+ AFB) 3 months after initiation of treatment(19-mm PPD; patient's pulmonary TB 5 years earlier was treatedfor 1 year). Patient 3 serum was obtained from a 46-year-old femalewith pulmonary TB (3+ AFB) 2 months after initiation of treatment(16-mm PPD; no history of BCGvaccination).

PBMC were obtained from either blood or apheresis product from healthy PPD-positive or -negative individuals by density centrifugationover Ficoll. None of the 12 PPD-positive donors had a historyof BCGimmunization.

Isolation of M. tuberculosis clones. M. tuberculosis H37Ra genomic DNA was isolated and sheared by sonication to a size range of 1 to 4 kilobases. M. tuberculosisH37Rv genomic DNA was partially digested with Sau3AI. Librarieswere constructed in Lambda ZapII (Stratagene, La Jolla, Calif.)by using EcoRI adaptors. Expression screening was performed usinga pool of patient sera preadsorbed with Escherichia coli (38).This resulted in the identification and purification of the followingseven immunoreactive clones: TbH2, TbH4, TbH5, TbH8, TbH9, TbH12,and TbH16. TbH2, TbH5, TbH8, TbH9, and TbH16 were recovered fromthe M. tuberculosis H37Ra library, and TbH4 and TbH12 were recoveredfrom the M. tuberculosis H37Rvlibrary.

Cloning of full-length genes mtb39a and mtb39b and the partial mtb39c was accomplished by isolating the 5' portion (approximately500 bp) of the TbH9 insert, random labeling with [³²P]dCTP, and screening approximately 75,000 PFU. DNA screeningwas performed as described previously (38). Seven positive cloneswere recovered, the insert sizes were determined by restrictiondigests, and the three largest were subjected to DNA sequenceanalysis (Applied Biosystems, Foster City, Calif.).

Expression of recombinant M. tuberculosis antigens. The recombinant antigens encoded by TbH4, TbH5, TbH9, TbH12, and TbH16 were expressed and purified. All of these antigensrepresented fusions with the N-terminal 4-kDa $beta$ -galactosidase,except rTbH4, which initiated within the clone. Induced bacterialpellets were lysed, and rTbH4, rTbH5, rTbH9, rTbH12, and rTbH16were recovered from the inclusion bodies. The recombinant proteinswere purified by ammonium sulfate precipitation and preparativegel separation by sodium dodecyl sulfate-10% polyacrylamide gelelectrophoresis (SDS-10% PAGE). Recombinant proteins were elutedfrom the gels and dialyzed in either phosphate-buffered saline(PBS) or 10 mM Tris (pH 7.4), the protein concentration was measuredby the Pierce (Rockford, Ill.) bicinchoninic acid assay, and puritywas assessed by SDS-PAGE followed by Coomassie bluestaining.

The insert of the TbH9 clone was engineered for expression by PCR, utilizing a primer containing an NdeI site, an N-terminalhistidine tag, and a primer encoding a termination site followedby a HindIII site. Amplified product was digested with NdeI andHindIII and ligated into pET17b. This clone was termed pET $Delta$ Mtb39A,and the recombinant protein encoded was termed r $Delta$ Mtb39A. Thisrecombinant protein contained the N-terminal residues encodedby the vector sequence MHHHHHHPGCR and followed by residues encodedby the M. tuberculosis DNAsequence.

The full-length mtb39a gene was engineered for expression as follows. PCR was performed by using primers which included flankingrestriction sites NdeI and HindIII and DNA sequence encoding anN-terminal 6-histidine tag. The PCR product was digested withNdeI and HindIII and ligated intopET17b.

Expression and purification of rMtb39A and r $Delta$ Mtb39A was performed as follows. Induced E. coli BL-21(pLysE) pellets were lysed,and the recombinant proteins were recovered in the inclusion bodies.Purification was accomplished by solubilization of pellets inbinding buffer (8 M urea-0.1 M NaPO₄-10 mM Tris [pH 8.0]) andmixed with Ni²⁺ nitrilotriacetic acid-agarose by rocking at room temperature.The mixture was placed in a column and washed with 8 M urea-0.1M NaPO₄-10 mM Tris (pH 6.3), and recombinant protein was theneluted with 8 M urea-0.1 M NaPO₄-10 mM Tris (pH 4.5). Fractionscontaining protein were combined and dialyzed against 10 mM Tris(pH 7.4). Under these purification conditions, complete solubilityas assessed by microfiltration (0.2 µM) was maintained at concentrationsup to 1 mg/ml. Purity of the two recombinants was assessed bySDS-PAGE followed by Coomassie blue staining and by high-performanceliquid chromatography (HPLC) analysis, which demonstrated greaterthan 95% purity. N-terminal sequencing using traditional Edmanchemistry with a Procise 494 protein sequencer (Perkin-Elmer,Applied Biosystems Division, Foster City, Calif.) was performedto confirm recombinant protein identities. Endotoxin was determinedto be less than 100 EU/mg by Limulus amoebocyte lysate (LAL) assay(BioWhittaker, Walkersville, Md.).

The DNA sequence encoding the M. tuberculosis 85B protein was engineered by PCR amplification of genomic DNA isolated fromthe H37Ra strain by using primers designed to amplify the entiremature secreted sequence (25), with the 5' primer encoding 6-histidineresidues. The PCR product was digested with NdeI and EcoRI andligated into the pET 17b plasmid. Plasmids were subsequently transformedinto competent E. coli BL-21(pLysE) cells for expression of therecombinant protein. Purification of recombinant M. tuberculosis85B (r85B) was performed in a manner similar to that describedfor rMtb39A and r $Delta$ Mtb39A.

All DNA manipulations of the various clones were confirmed by DNA sequencing to eliminate the possibility of the introductionof mutations by restriction, ligation, andPCR.

Mtb39A peptide synthesis. Mtb39A peptides were synthesized on a Rainin/PTI Symphony peptide synthesizer by using 9-fluorenylmethoxycarbonyl batch chemistrywith HBTU activation. Peptides were analyzed by reverse-phaseHPLC using a Vydac C18 column. Peptide molecular weights wereverified by using a matrix-assisted laser desorption/ionizationtime-of-flight massspectrometer.

Molecular analysis of M. tuberculosis clones. DNA was prepared by following the manufacturers' protocols (Qiagen, Chatsworth, Calif.; Promega, Madison, Wis.). DNA sequencingwas performed with an Automated Sequencer (model 373; AppliedBiosystems). DNA sequences and deduced amino acid sequences wereused in database searches (EMBL, GenBank, and Swiss and PIR andTranslated Release97).

Genomic DNA from mycobacterial strains was digested with PstI, separated by agarose gel electrophoresis, and blotted on Nytran(Schleicher & Schuell, Keene, N.H.). The mtb39a gene was labeledwith [³²P]dCTP by random oligonucleotide primers (Boehringer Mannheim,Indianapolis, Ind.) and used as a probe. Hybridization was performedat 65°C in 0.2 M Na-H₂PO₄-3.6 M NaCl-0.2 M EDTA overnight andwashed to a stringency of 0.075 M NaCl-0.0075 M sodium citrate(pH 7.0)-0.5% SDS at the temperature ofhybridization.

Immunoblot analysis. Antisera to rTbH9 and r85B were raised by using adult New Zealand White rabbits (R & R Rabbitry, Stanwood, Wash.) by an initialsubcutaneous (s.c.) delivery of 100 to 200 µg of recombinant antigenin 1 ml of incomplete Freund's adjuvant (IFA) (Bethesda ResearchLaboratories, Gaithersburg, Md.) together with 100 µg of muramyldipeptide (Calbiochem, La Jolla, Calif.), followed by two successives.c. immunizations of 75 to 100 µg of antigen in 1 ml of IFA at3-week intervals. A final intravenous boost of 75 to 100 µg ofantigen was delivered after four additional weeks, and serum wascollected 2 weekslater.

M. tuberculosis H37Rv lysate, culture filtrate proteins (CFP), PPD, and purified rMtb39A were subjected to SDS-PAGE in eithera 7.5 or 12% polyacrylamide gel and transferred to nitrocellulose.Filters were blocked with PBS (pH 7.4) containing 5% nonfat milkat 4°C overnight, washed three times in PBS-0.1% Tween 20 (PBS-T),and incubated for 1 h in rabbit sera (diluted 1:250 in PBS-T)on a rocker at room temperature. Filters were washed three timeswith PBS-T, and bound antibody was detected with 10⁵ cpm of ¹²⁵I-labeled protein A/ml followed byautoradiography.

Proliferation and cytokine production assays. PBMC were cultured in 96-well round-bottom plates (Corning Costar, Cambridge, Mass.) at 2 × 10⁵ cells/well in a volume of 200 µl. Antigens were tested in triplicateat 10 µg/ml and in some assays, antigens were titrated. Culturemedium consisted of RPMI medium with 10% pooled human serum and50 µg of gentamicin/ml. After 5 days of culture at 37°C in 5%CO₂, 50 µl of culture supernatant was carefully aspirated fordetermination of IFN- $gamma$ levels, and the plates were pulsed with1 µCi of tritiated thymidine/well. After culture for a further18 h, cells were harvested, and tritium uptake was determinedby using a gas scintillation counter. IFN- $gamma$ levels in culturesupernatants were determined by enzyme-linked immunosorbent assayELISA, as described previously (42).

Evaluation of Mtb39A in Mtb-infected DC. Monocyte-derived dendritic cells (DC) were prepared essentially according to the method of Romani et al. (37), by cultureof adherent PBMC in RPMI-10% human serum containing 10 ng of interleukin4 (Immunex Corporation, Seattle, Wash.)/ml and 30 ng of granulocyte-macrophagecolony-stimulating factor (Immunex)/ml for 5 to 7 days. Cellswere harvested with cell-dissociation medium (Sigma, St. Louis,Mo.) and seeded at 2 × 10⁴ cells per well in 96-well flat-bottom plates (Corning Costar)in 100 µl of RPMI-10% HS. Where indicated, M. tuberculosis wassubsequently added in 25 µl of medium. After 18 h, 5 × 10⁴ CD4⁺ D160TbH9-9 T cells were added in 100 µl of medium, and supernatantswere harvested after 18 to 24 h for determination of IFN- $gamma$ levels.D160TbH9-9 is an Mtb39A-specific T-cell clone generated by limitingdilution cloning of D160 PBMC stimulated withrMtb39A.

Naked DNA immunization. C57BL/6 mice were immunized intramuscularly (i.m.), three times, 1 month apart, with 100 µg of mtb39a DNA engineered in thepJA4304 vector (generous gift of James I. Mullins and Jim Arthos,University of Washington School of Medicine, Seattle, Wash.) lackingthe tPA signal peptide, or with control pJA4304 vector. The plasmidfor DNA immunizations was generated by PCR cloning of the mtb39acoding sequence into the expression vector JA4304. The 5' PCRprimer contained a consensus Kozak sequence (GGCCACC) just upstreamof the ATG initiator codon to allow efficient initiation of eukaryotictranslation. The PCR fragment was inserted as a HindIII-BglIIfragment into the corresponding restriction sites of the vector.Plasmid DNA preparations were done on a Qiagen column. Expressionof the mtb39a gene was confirmed upon transient transfection intoCos cells. Residual endotoxin content was measured by the LALassay and was below 0.001 EU/µg. In addition, groups of mice werealso immunized with 10⁴ BCG (once, s.c.) or simply injected with saline. Thirty daysafter the last immunization, the mice were challenged by the aerosolroute with approximately 100 CFU of M. tuberculosis Erdman. Protectionwas measured by enumerating the bacteriological burden (CFU) inthe mouselungs.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation and molecular characterization of mtb39a. Approximately 126,000 recombinant phage from M. tuberculosis H37Ra and M. tuberculosis H37Rv genomic libraries were screenedby using a pool of TB patient sera (see Materials and Methods).This resulted in the identification and purification of sevenserologically reactive clones. The recombinant antigens encodedby five of these clones were expressed andpurified.

Preliminary cellular assays with the five purified recombinant M. tuberculosis antigens, designated rTbH4, rTbH5, rTbH9, rTbH12,and rTbH16, demonstrated that only rTbH9 was effective in elicitingT-cell proliferation and production of IFN- $gamma$ using purified PBMCfrom healthy PPD-positive donors (data not shown). DNA sequenceanalysis of the region encoding the entire open reading frame(ORF) of TbH9 revealed the presence of 22 carboxy-terminal residuesderived from $lambda$ phage sequence, presumably due to an unusual ligationor recombination event during the formation of the library. TheTbH9 clone was reengineered to remove both the majority of the5' lacZ sequence and contaminating phage sequence and to add asix-histidine tag. This recombinant protein (r $Delta$ Mtb39A) was expressedand purified on a nickel column (Fig. 1).

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FIG. 1. Purification of rMtb39A and r $Delta$ Mtb39A proteins. Expression and purification of rMtb39A (A) and r $Delta$ Mtb39A (B) are shown with uninduced (lane 2) and induced (lane 3) E. coli lysates and 5 µg of purified proteins (lane 4). Molecular mass markers are shown in kDa (lane 1).

The TbH9 insert was used as a probe to clone the full-length gene from an M. tuberculosis H37Rv genomic library. Three clonesthat were recovered were sequenced, one of which encoded the full-lengthgene consisting of 391 amino acids, with a predicted mass of 39,162Da (Fig. 2), and the gene was designated mtb39a. Interestingly,the other two clones contained DNA sequences that were highlyrelated to, but nonidentical with, mtb39a and each other (datanot shown), indicating the presence of a family of at least threehighly related genes. The genes of these other family memberswere designated mtb39b and mtb39c. The DNA sequence analysis ofthese two clones revealed the full-length ORF encoded by mt39bwas present within one clone, but mtb39c was incomplete, lackingthe C-terminal portion. The sequence comparison of the proteinsencoded by mtb39a, mtb39b, and the N-terminal portion of mtb39c,referred to as Mtb39A, Mtb39B, and Mtb39C respectively, revealedamino acid identity ranging from 82 to 88% (Fig. 2). Databasesearches with the DNA sequences of mtb39a, mtb39b, and the N-terminalportion of mtb39c using the EMBL and GenBank database revealedidentities with recently deposited sequences derived from theSanger Center (Cambridge, United Kingdom). These sequences werelocated on cosmids I364, SCY02B10, and SCY13E12, respectively.The amino acid sequences from Mtb39A, Mtb39B, and Mtb39C haveidentity to hypothetical ORFs encoded within these cosmids (accessionno. e311073, e250360, and e316074, respectively). The hypotheticalORF identical to the partial Mtb39C amino acid sequence recoveredby cloning demonstrates that this family member is of approximatelythe same size as Mtb39A and Mtb39B, and the C-terminal portionis included for comparative purposes (Fig. 2). All three of theMtb39 family members belong to a group of 68 M. tuberculosis proteinsreferred to as the PPE family, based on the presence of this aminoacid sequence within the members, usually located near the N terminus(15). The cellular location of the PPE family of proteins hasnot been demonstrated, nor has a function been assigned to anyof the family members except one, a lipase (15). Hydropathyanalysis (22) of the Mtb39 amino acid sequences demonstratedthe presence of several extended hydrophobic regions in the threefamily members that could potentially serve as transmembrane domains(data not shown).

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FIG. 2. Comparison of amino acid sequences encoded by mtb39 genes. Identical residues are indicated by dots (.) and deletions are indicated by dashes (-). Amino acid residues present in rTbH9 are underlined. The carboxy-terminal portion of the Mtb39C ORF was recovered by database searching and extends from residues 360 to 393.

Genomic DNA from a number of mycobacterial species was analyzed by Southern blotting by using the mtb39a gene as a probe.The results demonstrate the presence of three highly related membersof the mtb39 gene family in various M. tuberculosis strains, consistentwith the number of genes recovered from the M. tuberculosis H37Rvgenomic library (Fig. 3). Based on restriction enzyme digest patterns,all three family members appear to be conserved in M. tuberculosisisolates, including clinical isolates M. tuberculosis Erdman (Fig.3) and M. tuberculosis C (data not shown). Hybridization consistentwith the presence of the three family members was also observedin M. bovis BCG, but no hybridization was detected in M. leprae,M. smegmatis, M. vaccae, M. gordonae, M. chelonae, M. fortuitum,M. scrofulaceum, and M. avium.

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FIG. 3. Southern blot analysis of mtb39 genes. Genomic DNA (2.5 µg) from mycobacterial strains was digested with PstI, separated by agarose gel electrophoresis, and blotted onto Nytran. The mtb39a gene was labeled with [³²P]dCTP by random oligonucleotide primers and used as a probe. Molecular sizes in kilobases are shown.

To further characterize native and recombinant Mtb39A, full-length recombinant Mtb39A (rMtb39A) was expressed and purified(Fig. 1). To characterize the native M. tuberculosis protein encodedby mtb39a, a rabbit antiserum was raised to rTbH9 and used inan immunoblot of M. tuberculosis lysate. Mtb39A protein couldbe detected in M. tuberculosis lysate at approximately 40 kDa,in agreement with the predicted mass. However, no protein couldbe detected in M. tuberculosis CFP (Fig. 4). Integrity of theCFP was verified by Coomassie staining (data not shown) and byimmunoblotting using a rabbit antiserum raised against purifiedr85B, a known secreted M. tuberculosis protein (Fig. 4).

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FIG. 4. Characterization of native Mtb39A. M. tuberculosis H37Rv lysate (2.5 µg; lane 1), 2.5 µg of culture filtrate protein (lane 2), 50 ng of purified rMtb11 (recombinant 11-kDa M. tuberculosis antigen [unpublished results]) (lane 3), 50 ng of purified r $Delta$ Mtb39A (lane 4), and 50 ng of purified recombinant antigen 85B (lane 5) were subjected to SDS-PAGE, transferred to nitrocellulose, and reacted with rabbit antisera generated against r $Delta$ Mtb39A (A) or recombinant antigen 85B (B). Molecular markers in kDa are indicated.

PBMC responses to Mtb39A. PBMC from 12 PPD-positive and 12 PPD-negative donors, all with no history of TB, were analyzed for T-cell proliferation andIFN- $gamma$ production in response to CFP, tetanus toxoid, purifiedr $Delta$ Mtb39A, purified rMtb39A, and, for comparative purposes, r85B.The proliferation results (Fig. 5A and B) indicate responses bythe majority of the 12 PPD-positive donors to r $Delta$ Mtb39A, whileonly very weak or negative responses were observed in the PPD-negativedonors. Using an arbitrary cutoff of a stimulation index (SI)of 5 for a positive response, the full-length protein rMtb39Aelicited proliferative responses in 9 of 12 PPD-positive donorstested, with responses seen in none of the 12 PPD-negative donors.In addition, the majority of PPD-positive individuals respondingto both r $Delta$ Mtb39A and rMtb39A, had greater responses to rMtb39A(the mean SI for rMtb39A was 32.4, compared with 19.4 for r $Delta$ Mtb39A),suggesting the recognition of multiple T-cell epitopes withinrMtb39A, with some located in the N-terminal and/or C-terminalregions not present within r $Delta$ Mtb39A. A similar number of donors(8 of 12) responded to r85B, although the mean SI was considerablylower with r85B (15.3) compared with that of Mtb39A (32.4). Inaddition, r85B induced a response (SI, >5) in 2 of 12 of the PPD-negativedonors. The response to tetanus toxoid was similar in both groups,with 11 of 12 PPD-positive and -negative donors responding withSIs of greater than 5.

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FIG. 5. Proliferation and IFN- $gamma$ production by PBMC from PPD-positive and -negative donors to CFP, tetanus toxoid, r $Delta$ Mtb39A, rMtb39A, and r85B. Proliferation was measured in PBMC from PPD-positive donors (n = 12) and PPD-negative donors (n = 12). PBMC (2 × 10⁵ cells/well) were cultured in the presence of antigen (10 µg/ml) for 5 days. After 5 days, 50 µl of culture supernatant was carefully aspirated for determination of IFN- $gamma$ levels by ELISA, and the plates were pulsed with tritiated thymidine. After culture for a further 18 h, cells were harvested, and tritium uptake was determined by using a gas scintillation counter. Proliferation results are reported as an SI (counts per minute of cultures with antigen/counts per minute of medium control cultures). The number of responses that have an SI of greater than 100 is indicated in parentheses.

The IFN- $gamma$ production responses (Fig. 5C and D) were similar to the proliferative responses, with the majority of PPD-positiveindividuals responding to both r $Delta$ Mtb39A and rMtb39A, and low orno response observed in the PPD-negativedonors.

Four of the strongest responders to rMtb39A were selected for more detailed analysis. The results of antigen titration experimentsindicated that very low amounts of rMtb39A protein were sufficientto elicit significant responses, such that in some donors as littleas 1 ng of antigen/ml elicited a maximal response (Fig. 6). PBMCfrom these donors all made strong IFN- $gamma$ responses to rMtb39A thatcorrelated well with their proliferative responses. Stronger proliferationand IFN- $gamma$ responses to the full-length protein were noted overthe entire titration curve with several donors, again suggestingthe presence of additional T-cell epitopes in the N-terminal orC-terminal region of rMtb39A that were not present in r $Delta$ Mtb39A.

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FIG. 6. Dose response of PBMC from PPD-positive donors to r $Delta$ Mtb39A and rMtb39A. Proliferation and IFN- $gamma$ production to r $Delta$ Mtb39A and rMtb39A were measured in PBMC from four PPD-positive donors. After 5 days, 50 µl of culture supernatant was carefully aspirated for determination of IFN- $gamma$ levels by ELISA, and the plates were pulsed with tritiated thymidine. After culture for a further 18 h, cells were harvested, and tritium uptake was determined by using a gas scintillation counter.

To determine the complexity of T-cell epitopes being recognized by the PPD-positive donors, overlapping peptides across theentire ORF of Mtb39A were synthesized and analyzed for the abilityto elicit T-cell proliferation from PBMC (Fig. 7). Responses bythe four donors tested indicated the presence of at least 10 distinctT-cell epitopes within rMtb39A. The intensity and complexity ofresponses varied greatly among the different donors, from therestricted response observed with donor 7 (responding to onlythree peptides) to the broad response observed with donor 160,where proliferative responses to 26 of the 38 peptides were observed.All peptides were tested on PBMC from eight PPD-negative donorsand none of the peptides elicited a response (SI, >5) from anyof the donors (data not shown).

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FIG. 7. PBMC responses from PPD-positive donors to r $Delta$ Mtb39A, rMtb39A, and peptides derived from the amino acid sequence. Proliferation to r $Delta$ Mtb39A, rMtb39A and peptides based on Mtb39A amino acid sequence was measured in PBMC from four PPD-positive donors. PBMC (2 × 10⁵ cells/well) were cultured in the presence of antigen (10 µg/ml) for 5 days. After 5 days, 50 µl of culture supernatant was carefully aspirated for determination of IFN- $gamma$ levels by ELISA, and the plates were pulsed with 1 µCi of tritiated thymidine/well. After culture for a further 18 h, cells were harvested, and tritium uptake was determined by using a gas scintillation counter. Proliferation results to the antigens are reported as an SI (counts per minute of cultures with antigen/counts per minute of medium control cultures).

The peptide results are also consistent with the differential responses to r $Delta$ Mtb39A and rMtb39A in donor 7, donor 62, anddonor 131 that were observed. In all three donors, PBMC yieldedgreater proliferative responses to the full-length protein thanto the truncated portion. Examination of the profile of stimulatorypeptides for these three donors revealed that all recognize additionalpeptides in the N-terminal or C-terminal region of Mtb39 not includedin r $Delta$ Mtb39A. The response to r $Delta$ Mtb39A was not significantly reducedin donor 160, where the majority of stimulatory peptides are locatedwithin regions present in both recombinant proteins and the overwhelmingresponse to these epitopes likely masks any additivity by reactiveN-terminal and C-terminalpeptides.

Mtb39A is presented by M. tuberculosis-infected DC. An Mtb39A-specific CD4⁺ T-cell clone, termed D160TbH9-9, was utilized to confirm the immunoblot results indicating that Mtb39Awas not detectable in M. tuberculosis CFP. Blood-derived DC werechosen for these studies because of their superior antigen-presentingcapabilities compared with monocytes and because they are amenableto infection with M. tuberculosis (24). Autologous DC were pulsedwith PPD, CFP, or rMtb39A and incubated with D160TbH9-9 cells,and IFN- $gamma$ production was measured. Production of IFN- $gamma$ was observedwhen the dendritic cells were pulsed with PPD or rMtb39A but notwhen pulsed with CFP (Fig. 8A), consistent with the previous immunoblotdata indicating that Mtb39A was not present in CFP. An Mtb39A-specificCD4⁺ T-cell clone derived from donor 131 also showed strong reactivitywith PPD but no reactivity with CFP (data not shown). The D160TbH9-9clone was then used to determine if Mtb39A could be detected inM. tuberculosis-infected DC. When autologous DC infected withM. tuberculosis were incubated with D160TbH9-9 cells, productionof IFN- $gamma$ was observed (Fig. 8B), indicating that Mtb39A expressedby M. tuberculosis can be processed and presented by infectedDC.

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FIG. 8. Mtb39A is present in Mtb-infected DC. A total of 5 × 10⁴ Mtb39A-specific CD4⁺ T-cell clone D160TbH9-9 cells were incubated with 2 × 10⁴ autologous DC that had either been incubated with PPD, CFP, or rMtb39A at a concentration of 10 µg/ml (A) or incubated for 18 h with M. tuberculosis H37Rv (MOI, 50) (B). Supernatants were collected after 18 h and assessed for the presence of IFN- $gamma$ by ELISA.

Responses to Mtb39A DNA immunization in murine protection model. Because immunity to tuberculosis is apparently dependent on both CD4⁺ and CD8⁺ T-cell responses, experiments were designed to investigate theprotection potential of mtb39a delivered in a naked DNA format.These experiments were supported by previous immunogenicity studieswhich demonstrated that mtb39a engineered in the expression vectorpJA4304 under the CMV promoter induced both CD4⁺ and CD8⁺ T-cell responses (data not shown). C57BL/6 mice were immunizedthree times with pJA4304 vector DNA or the mtb39a construct andchallenged with aerosolized viable and virulent M. tuberculosis.Resistance was assessed 4 weeks after infection by enumeratingthe bacteriological burden in the lungs. Figure 9 illustratesthe results and shows that mice immunized with mtb39a DNA wereable to develop lung protection against tuberculosis. This protectionwas not as strong as that induced by BCG vaccination but was significantin that the bacteriological burden in the lungs of mtb39a DNAimmunized mice was five times smaller than that observed for miceinfected with control DNA or with saline.

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FIG. 9. mtb39a DNA immunization in the murine protection model. Groups of five C57BL/6 mice were immunized i.m. three times 1 month apart with 100 µg of mtb39a DNA or with control DNA (Vector). In addition, groups of five mice were also immunized with BCG (once) or simply injected with saline. Thirty days after the last immunization, the mice were challenged by the aerosol route with approximately 100 CFU of M. tuberculosis Erdman. Protection was measured by enumerating the bacteriological burden (CFU) in the mouse lungs, shown as log₁₀ CFU.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

An initial requirement a TB candidate vaccine antigen must meet is that it is recognized by the immune system during the courseof infection in the majority of individuals of the target population.To assess candidate M. tuberculosis antigens, we have used a panelof PPD-positive donors, with no history of tuberculosis disease.We have purposely chosen an ethnically diverse group, and haveused T-cell proliferation and production of IFN- $gamma$ from in vitro-stimulatedPBMC to measure recognition of the relevant antigen during previousexposure to M. tuberculosis. The presumption that strong IFN- $gamma$ responses are required for protective immunity is supported bythe fact that both mice and humans that are deficient in IFN- $gamma$ production or signaling in vivo are susceptible to mycobacterialinfections (16, 18, 20, 28). This preliminary screeningof candidate antigens has identified Mtb39A as an antigen recognizedby the majority of M. tuberculosis infected individuals withoutevident disease, with strong T-cell proliferation and IFN- $gamma$ productionobserved in 9 of 12 donors tested. Often, the responses to thissingle recombinant antigen that were observed were similar inmagnitude to that elicited by the complex mixture of proteinspresent in CFP and were superior to those elicited by r85B. Equallystriking is the ability of Mtb39A to elicit responses from PPD-positivedonors at exceedingly low antigen concentrations, suggesting thatM. tuberculosis antigens expressed at low levels retain the abilityto trigger potent immuneresponses.

It is likely that a candidate vaccine antigen for M. tuberculosis will need to contain multiple T-cell epitopes to affordprotection in an outbred human population. Experiments using overlappingpeptides on a small panel of donors confirmed the presence ofat least 10 distinct T-cell epitopes contained within Mtb39A recognizedby PBMC from human PPD-positive donors. The recovery of threehighly related Mtb39 family members poses the question of antigenimmunogenicity versus a cross-reactive elicitation of a T-cellresponse. A broad response, such as that observed in donor 160,indicates that Mtb39A was the antigen against which the immunesystem developed a response during the infection by M. tuberculosis.Less clear are more restricted responses, as was observed in donor7, in which only three peptides appeared to be recognized. A completeunderstanding of the potential contributions by all three familymembers will rely on the synthesis and testing of overlappingpeptides derived from all three amino acid sequences in the regionsofdivergence.

The data generated with the rMtb39A and derived peptides indicate an abundance of T-cell epitopes recognized by healthy PPD-positivedonor PBMC. However, these data are based entirely on either syntheticor recombinant molecules. Indeed, native Mtb39A may contain additionalepitopes that cannot be detected by using these synthetic or recombinantforms, since the possibility of differential processing due topotential conformational differences between these forms and nativeMtb39A exists. The low level of expression of native Mtb39A inM. tuberculosis cultures makes testing this a difficult proposition,since purification will likely result in some contaminating M.tuberculosis proteins which could contribute to the response inT-cellassays.

Recent research with the goal of identifying TB antigens recognized by human T cells has focused on antigens present in M.tuberculosis CFP. This focus has arisen from the observation thatlive mycobacteria, but not heat-killed preparations, elicit protectiveimmunity in animal models (31). Subsequent experiments in miceand guinea pigs demonstrated that the mixture of antigens thatcomprise CFP could confer protection (3, 32, 33). Theseprotection experiments indicate that immunologically relevantantigens are present in CFP, and efforts have resulted in theidentification of a number of these antigens capable of elicitingCD4⁺ T-cell recall responses, including the Ag 85 complex, ESAT-6,MPT64, and the 10-kDa antigen (1, 8, 19, 23, 35).The results presented here provide evidence that potent T-cellantigens from TB are not exclusively present in CFP. This assertionis based upon two lines of evidence. First, data demonstratedthat Mtb39A is a very potent antigen based upon its ability tostimulate strong T-cell proliferation and IFN- $gamma$ production byPBMC from PPD-positive but not PPD-negative individuals. Second,Mtb39A could not be detected in CFP by either a high-titer polyclonalMtb39A antiserum or by a very sensitive CD4⁺ T-cell clone cultured with DC pulsed withCFP.

More important than whether an antigen is present within CFP or PPD is whether the antigen is expressed, processed, and presentedby major histocompatibility complex molecules upon infection ofcells with TB. We have demonstrated that the Mtb39A-specific CD4⁺ T-cell clone could detect the presence of Mtb39A upon infectionof autologous DC with TB. Although the data presented here areinsufficient to claim that M. tuberculosis expresses Mtb39A duringinfection of DC, they do demonstrate the ability of the proteinto be processed and presented in the context of an infection,either by the infected DC or uninfected neighboringDC.

Utilization of the host immune response provides a direct method to distinguish relevant antigens in a complex lysate or geneexpression library. We have used a two-step expression cloningapproach, initially screening with antisera from individuals withactive TB, followed by evaluation of purified recombinant proteinsbased on T-cell stimulation, in an attempt to isolate novel T-cellantigens. Although the majority of M. tuberculosis antigens recoveredby their reactivity with TB patient sera did not elicit significantcellular responses, one potent T-cell antigen, Mtb39A, was identifiedthrough this approach. We have utilized a process that startswith human reactivity (both T cell and serological) to identifycandidate antigens, and proceeded by characterizing these by testinghuman T-cell responses from protected individuals. We then proceededto animal studies, and evaluated both immunogenicity and protectivecharacteristics of the antigens. This approach clearly differsfrom that used by many other researchers in this field, whereinitial tests of candidate antigens involve animal immunogenicityand protection studies using native M. tuberculosis antigens,followed by evaluation of human responses to the antigens. Itis worth noting that the validity of either of these approachesto recover relevant antigens that would comprise an effectiveM. tuberculosis vaccine for humans is as yet uncertain. Presumably,the best candidate vaccine antigens would be those that are ableto provide protection in at least one of the animal models andare known to be recognized by the immune systems of humans infectedwith M. tuberculosis.

	ACKNOWLEDGMENTS

We thank Paul Sleath for assistance with synthetic peptides, Tom Vedvick for N-terminal sequencing of recombinant proteins,and Steve Johnson and John Webb for M. tuberculosis H37Ra andH37Rv genomic libraries. We thank James I. Mullins and Jim Arthosfor kindly providing the pJA4304 plasmid. We thank Dan Hoppe forDNA sequencing efforts and Karen Kinch for assistance in manuscriptpreparation.

Murine protection experiments were performed on NIH program AI-75320.

	FOOTNOTES

^* Corresponding author. Mailing address: Corixa Corporation, 1124 Columbia St., Suite 200, Seattle, WA 98104. Phone: (206) 754-5701.Fax: (206) 754-5715. E-mail: dillon{at}corixa.com.

Editor: S. H. E. Kaufmann

	REFERENCES

Top Abstract Introduction Materials and Methods Results Discussion References

1.	Abou Zeid, C., T. L. Ratliff, H. G. Wiker, M. Harboe, J. Bennedsen, and G. A. Rook. 1988. Characterization of fibronectin-binding antigens released by Mycobacterium tuberculosis and Mycobacterium bovis BCG. Infect. Immun. 56:3046-3051[Abstract/Free Full Text].
2.	Amara, R. R., and V. Satchidanandam. 1996. Analysis of a genomic DNA expression library of Mycobacterium tuberculosis using tuberculosis patient sera: evidence for modulation of the host immune response. Infect. Immun. 64:3765-3771[Abstract].
3.	Andersen, P. 1994. Effective vaccination of mice against Mycobacterium tuberculosis infection with a soluble mixture of secreted mycobacterial proteins. Infect. Immun. 62:2536-2544[Abstract/Free Full Text].
4.	Andersen, P., A. B. Andersen, A. L. Sorensen, and S. Nagai. 1995. Recall of long-lived immunity to Mycobacterium tuberculosis infection in mice. J. Immunol. 154:3359-3372[Abstract].
5.	Arachi, A. 1991. The global tuberculosis situation and the new control strategy of the World Health Organization. Tubercle 72:1-6[Medline].
6.	Baily, G. V. 1981. BCG vaccination after the Madras study. Lancet i:309-310.
7.	Barnes, P. F., and S. A. Barrows. 1993. Tuberculosis in the 1990s. Ann. Intern. Med. 119:400-410[Abstract/Free Full Text].
8.	Barnes, P. F., V. Mehra, B. Rivoire, S. J. Fong, P. J. Brennan, M. S. Voegtline, P. Minden, R. A. Houghten, B. R. Bloom, and R. L. Modlin. 1992. Immunoreactivity of a 10-kDa antigen of Mycobacterium tuberculosis. J. Immunol. 148:1835-1840[Abstract].
9.	Barnes, P. F., A. B. Bloch, P. T. Davidson, and D. E. Snider, Jr. 1991. Tuberculosis in patients with human immunodeficiency virus infection. N. Engl. J. Med. 324:1644-1650[Medline].
10.	Braun, M. M., and G. Cauthen. 1992. Relationship of the human immunodeficiency virus epidemic to pediatric tuberculosis and bacillus Calmette-Guerin immunization. Pediatr. Infect. Dis. J. 11:220-227[Medline].
11.	Calmette, A., C. Guerin, L. Negre, and A. Boquet. 1926. Prémunition des nouveaux-nés contre la tuberculose par le vaccin BCG, 1921-1926. Ann. Inst. Pasteur (Paris) 40:89-133.
12.	Chaisson, R. E., G. F. Schecter, C. P. Theuer, G. W. Rutherford, D. F. Echenberg, and P. C. Hopewell. 1987. Tuberculosis in patients with the acquired immunodeficiency syndrome. Clinical features, response to therapy, and survival. Am. Rev. Respir. Dis. 136:570-574[Medline].
13.	Coates, A. R. M., J. Hewitt, B. W. Allen, J. Ivanyi, and D. A. Mitchison. 1981. Antigenic diversity of Mycobacterium tuberculosis and Mycobacterium bovis detected by means of monoclonal antibodies. Lancet ii:167-169.
14.	Colditz, G. A., T. F. Brewer, C. S. Berkey, M. E. Wilson, E. Burdik, H. V. Fineburg, and F. Mosteller. 1994. Efficacy of BCG vaccine in the prevention of tuberculosis. Meta-analysis of the published literature. JAMA 271:698-702[Abstract].
15.	Cole, S. T., R. Brosch, J. Parkhill, T. Garnier, C. Churcher, D. Harris, S. V. Gordon, K. Eiglmeier, S. Gas, C. E. Barry III, F. Tekaia, K. Badcock, D. Basham, D. Brown, T. Chillingworth, R. Conner, R. Davies, K. Devlin, T. Feltwell, S. Gentles, N. Hamlin, S. Holroyd, T. Hornsby, K. Jagels, A. Krogh, J. McLean, S. Moule, L. Murphy, K. Oliver, J. Osborne, M. A. Quail, M.-A. Rajandream, J. Rogers, S. Rutter, K. Seeger, J. Skelton, R. Squares, S. Squares, J. E. Sulston, K. Taylor, S. Whitehead, and B. G. Barrell. 1998. Deciphering the biology of Mycobacterium tuberculosis from the complete genome sequence. Nature 393:537-544[Medline].
16.	Cooper, A. M., D. K. Dalton, T. A. Stewart, J. P. Griffen, D. G. Russel, and I. M. Orme. 1993. Disseminated tuberculosis in interferon- $gamma$ gene-disrupted mice. J. Exp. Med. 178:2243-2247[Abstract/Free Full Text].
17.	Engers, H. D., V. Houba, J. Bennedsen, T. M. Buchanan, S. D. Chapars, G. Kadival, O. Closs, J. R. David, J. D. A. van Embden, T. Godal, S. A. Mustafa, J. Ivanyi, D. B. Young, S. H. E. Kaufmann, A. G. Komenko, A. H. J. Kolk, M. Kubin, J. A. Louis, P. Minden, T. M. Shinnick, L. Trnka, and R. A. Young. 1986. Results of a World Health Organization sponsored workshop to characterize antigens recognized by mycobacterium-specific monoclonal antibodies. Infect. Immun. 51:718-720[Free Full Text].
18.	Flynn, J. L., J. Chan, K. J. Triebold, D. K. Dalton, T. A. Stewart, and B. R. Bloom. 1993. An essential role for IFN- $gamma$ in resistance to M. tuberculosis infection. J. Exp. Med. 178:2248-2253.
19.	Haslov, K., A. Andersen, S. Nagal, A. Gottschau, T. Sorensen, and P. Andersen. 1995. Guinea pig cellular immune responses to proteins secreted by Mycobacterium tuberculosis. Infect. Immun. 63:804-810[Abstract].
20.	Jouanguy, E., F. Altare, S. Lamhamedi, P. Revy, J. Emile, M. Newport, M. Levin, S. Blanche, E. Seboun, and J. Casanova. 1996. Interferon-gamma-receptor deficiency in an infant with fatal Bacille Calmette-Guerin infection. N. Engl. J. Med. 335:1956-1961[Free Full Text].
21.	Kochi, A. 1991. The global tuberculosis situation and the new control strategy of the World Health Organization. Tubercle 72:1-6.
22.	Kyte, J., and R. F. Doolittle. 1982. A simple method for displaying the hydropathic character of a protein. J. Mol. Biol. 157:105-132[Medline].
23.	Launois, P., R. DeLeys, M. N. Niang, A. Drowart, M. Andrien, P. Dierckx, J. L. Cartel, J. L. Sarthou, J. P. Van Vooren, and K. Huygen. 1994. T-cell-epitope mapping of the major secreted mycobacterial antigen Ag85A in tuberculosis and leprosy. Infect. Immun. 62:3679-3687[Abstract/Free Full Text].
24.	Lewinsohn, D. M., M. R. Alderson, A. L. Briden, S. R. Riddell, S. G. Reed, and K. H. Grabstein. 1998. Characterization of human CD8+ T cells reactive with Mycobacterium tuberculosis-infected antigen-presenting cells. J. Exp. Med. 187:1633-1640[Abstract/Free Full Text].
25.	Matsuo, K., R. Yamaguchi, A. Yamazaki, H. Tasaka, and T. Yamada. 1988. Cloning and expression of the Mycobacterium bovis BCG gene for extracellular alpha antigen. J. Bacteriol. 170:3847-3854[Abstract/Free Full Text].
26.	Müller, I., S. P. Cobbold, H. Waldmann, and S. H. E. Kaufmann. 1987. Impaired resistance to Mycobacterium tuberculosis infection after selective in vivo depletion of L3T4⁺ and Lyt-2⁺ T cells. Infect. Immun. 55:2037-2041[Abstract/Free Full Text].
27.	Narrain, J. P., M. C. Raviglione, and A. Kochi. 1992. HIV-associated tuberculosis in developing countries: epidemiology and strategies for prevention. Tuberc. Lung Dis. 73:311-321[Medline].
28.	Newport, M. J., C. M. Huxley, S. Huston, C. M. Hawrylowicz, B. A. Oostra, R. Williamson, and M. Levin. 1997. A mutation in the interferon-gamma-receptor gene and susceptibility to mycobacterial infection. N. Engl. J. Med. 335:1941-1949[Abstract/Free Full Text].
29.	Orme, I. M., and F. M. Collins. 1984. Adoptive protection of the Mycobacterium tuberculosis-infected lung. Dissociation between cells that passively transfer protective immunity and those that transfer delayed type hypersensitivity to tuberculin. Cell. Immunol. 84:113-120[Medline].
30.	Orme, I. M. 1987. The kinetics of emergence and loss of mediator T lymphocytes acquired in response to infection with Mycobacterium tuberculosis. J. Immunol. 138:293-298[Abstract].
31.	Orme, I. M. 1988. Induction of nonspecific acquired resistance and delayed-type hypersensitivity, but not specific acquired resistance in mice inoculated with killed mycobacterial vaccines. Infect. Immun. 56:3310-3312[Abstract/Free Full Text].
32.	Orme, I. 1994. Protective and memory immunity in mice infected with Mycobacterium tuberculosis. Immunobiology 191:503-508[Medline].
33.	Pal, P. G., and M. A. Horwitz. 1992. Immunization with extracellular proteins of Mycobacterium tuberculosis induces cell-mediated immune responses and substantial protective immunity in a guinea pig model of pulmonary tuberculosis. Infect. Immun. 60:4781-4792[Abstract/Free Full Text].
34.	Pedrazanni, T., K. Hug, and J. A. Louis. 1987. Importance of L3T4+ and Lyt-2+ T cells in the immunologic control of infection with Mycobacterium bovis strain bacillus Calmette-Guerin in mice. J. Immunol. 139:2032-2037[Abstract].
35.	Roche, P. W., J. A. Triccas, D. T. Avery, T. Fifis, H. Billman-Jacobe, and W. J. Britton. 1994. Differential T cell responses to mycobacteria-secreted proteins distinguish vaccination with Bacille Calmette-Guerin from infection with Mycobacterium tuberculosis. J. Infect. Dis. 170:1326-1330[Medline].
36.	Romain, F., J. Augier, P. Pescher, and G. Marchal. 1993. Isolation of a proline-rich mycobacterial protein eliciting delayed-type hypersensitivity reactions only in guinea pigs immunized with living mycobacteria. Proc. Natl. Acad. Sci. USA 90:5322-5326[Abstract/Free Full Text].
37.	Romani, N., S. Gruner, D. Brang, E. Kampgen, A. Lenz, B. Trockenbacher, G. Konwalinka, P. O. Fritsch, R. M. Steinman, and G. Schuler. 1994. Proliferating dendritic cell progenitors in human blood. J. Exp. Med. 180:83-93[Abstract/Free Full Text].
38.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
39.	Sanchez, F. O., J. I. Rodriguez, G. Agudelo, and L. F. Garcia. 1994. Immune responsiveness and lymphokine production in patients with tuberculosis and healthy controls. Infect. Immun. 62:5673-5678[Abstract/Free Full Text].
40.	Schaaf, H. S., P. Botha, N. Beyers, R. P. Gie, H. A. Vermeulen, P. Groenwald, G. J. Coetzee, and P. R. Donald. 1996. The 5-year outcome of multidrug resistant tuberculosis patients in the Cape Province of South Africa. Trop. Med. Int. Health 1:718-722[Medline].
41.	Shinnick, T. M. 1987. The 65-kilodalton antigen of Mycobacterium tuberculosis. J. Bacteriol. 169:1080-1088[Abstract/Free Full Text].
42.	Skeiky, Y. A. W., J. A. Guderian, D. R. Benson, O. Bacelar, E. M. Carvalho, M. Kubin, R. Badaro, G. Trinchieri, and S. G. Reed. 1995. A recombinant Leishmania antigen that stimulates human peripheral blood mononuclear cells to express a Th1-type cytokine profile and to produce interleukin 12. J. Exp. Med. 181:1527-1537[Abstract/Free Full Text].
43.	Von Reyn, C. F., C. J. Clements, and J. M. Mann. 1987. Human immunodeficiency virus infection and routine childhood immunization. Lancet ii:669-672.
44.	Weltman, A. C., and D. N. Rose. 1993. The safety of Bacille Calmette-Guerin vaccination in HIV infection and AIDS. AIDS 7:149-157[Medline].

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Le Roy, E., Baron, M., Faigle, W., Clement, D., Lewinsohn, D. M., Streblow, D. N., Nelson, J. A., Amigorena, S., Davignon, J.-L. (2002). Infection of APC by Human Cytomegalovirus Controlled Through Recognition of Endogenous Nuclear Immediate Early Protein 1 by Specific CD4+ T Lymphocytes. J. Immunol. 169: 1293-1301 [Abstract] [Full Text]
Flyer, D. C., Ramakrishna, V., Miller, C., Myers, H., McDaniel, M., Root, K., Flournoy, C., Engelhard, V. H., Canaday, D. H., Marto, J. A., Ross, M. M., Hunt, D. F., Shabanowitz, J., White, F. M. (2002). Identification by Mass Spectrometry of CD8+-T-Cell Mycobacterium tuberculosis Epitopes within the Rv0341 Gene Product. Infect. Immun. 70: 2926-2932 [Abstract] [Full Text]
Delogu, G., Li, A., Repique, C., Collins, F., Morris, S. L. (2002). DNA Vaccine Combinations Expressing Either Tissue Plasminogen Activator Signal Sequence Fusion Proteins or Ubiquitin-Conjugated Antigens Induce Sustained Protective Immunity in a Mouse Model of Pulmonary Tuberculosis. Infect. Immun. 70: 292-302 [Abstract] [Full Text]
Delogu, G., Brennan, M. J. (2001). Comparative Immune Response to PE and PE_PGRS Antigens of Mycobacterium tuberculosis. Infect. Immun. 69: 5606-5611 [Abstract] [Full Text]
Coler, R. N., Campos-Neto, A., Ovendale, P., Day, F. H., Fling, S. P., Zhu, L., Serbina, N., Flynn, J. L., Reed, S. G., Alderson, M. R. (2001). Vaccination with the T Cell Antigen Mtb 8.4 Protects Against Challenge with Mycobacterium tuberculosis. J. Immunol. 166: 6227-6235 [Abstract] [Full Text]
Olsen, A. W., van Pinxteren, L. A. H., Okkels, L. M., Rasmussen, P. B., Andersen, P. (2001). Protection of Mice with a Tuberculosis Subunit Vaccine Based on a Fusion Protein of Antigen 85B and ESAT-6. Infect. Immun. 69: 2773-2778 [Abstract] [Full Text]
Lewinsohn, D. M., Zhu, L., Madison, V. J., Dillon, D. C., Fling, S. P., Reed, S. G., Grabstein, K. H., Alderson, M. R. (2001). Classically Restricted Human CD8+ T Lymphocytes Derived from Mycobacterium tuberculosis-Infected Cells: Definition of Antigenic Specificity. J. Immunol. 166: 439-446 [Abstract] [Full Text]
Skeiky, Y. A. W., Ovendale, P. J., Jen, S., Alderson, M. R., Dillon, D. C., Smith, S., Wilson, C. B., Orme, I. M., Reed, S. G., Campos-Neto, A. (2000). T Cell Expression Cloning of a Mycobacterium tuberculosis Gene Encoding a Protective Antigen Associated with the Early Control of Infection. J. Immunol. 165: 7140-7149 [Abstract] [Full Text]
Dillon, D. C., Alderson, M. R., Day, C. H., Bement, T., Campos-Neto, A., Skeiky, Y. A. W., Vedvick, T., Badaro, R., Reed, S. G., Houghton, R. (2000). Molecular and Immunological Characterization of Mycobacterium tuberculosis CFP-10, an Immunodiagnostic Antigen Missing in Mycobacterium bovis BCG. J. Clin. Microbiol. 38: 3285-3290 [Abstract] [Full Text]
Musser, J. M., Amin, A., Ramaswamy, S. (2000). Negligible Genetic Diversity of Mycobacterium tuberculosis Host Immune System Protein Targets: Evidence of Limited Selective Pressure. Genetics 155: 7-16 [Abstract] [Full Text]
Alderson, M. R., Bement, T., Day, C. H., Zhu, L., Molesh, D., Skeiky, Y. A. W., Coler, R., Lewinsohn, D. M., Reed, S. G., Dillon, D. C. (2000). Expression Cloning of an Immunodominant Famil